Oxidation of NADH with vanadyl ion: detection of superoxide ion as a reaction intermediate

Inorganica

Chimica

Acta,

188 (1991)

Oxidation of NADH reaction intermediate Toshihiko

Ozawa*,

of Chemical

Division

Akira

163-165

163

with vanadyl

ion: detection

of superoxide

ion as a

Hanaki

Pharmacology,

National

Institute

of Radiological

Sciences,

9-1, Anagawa-4-chome,

Chiba-shi

260

(Japan)

and Fumie Kyoritus

Takazawa

College

of Pharmacy,

I-5-30,

Shibakoen,

Minato-ku,

Tokyo

105 (Japan)

(Received May 22, 1991)

Abstract NADH has been not oxidized by the V(V) ion, but by the V(W) ion. This oxidation occurred in the presence of oxygen, but did not proceed in the presence of superoxide dismutase (SOD) which can dismutate superoxide ion (O,-) to oxygen (0,) and hydrogen peroxide (H,O,). Further, the 02- spin add,uct of cr-(4-pyridyl-1-oxide)-N-t-butymitrone (POBN) has been observed during the oxidation of NADH with the V(W) ion. From these results, it is concluded that 02- is generated as a reaction intermediate during the oxidation of NADH by the V(W) ion in the presence of oxygen.

Introduction

‘$

fJi-N-C(CM)3 It is thought that vanadium is an essential element for living organisms and its ion potentially accelerates the oxidation of NADH in the membranes [l-9]. Recently, the reactivities of vanadate ion (V(V)) [4] and its reducing species, vanadyl ion (V(IV)) [lo], towards NADH have been reported independently. However, at present there is no evidence as to which ion is the active species for NADH. We have examined spectroscopically the reaction of the V(IV) ion or the V(V) ion with NADH and the transient intermediate generated from these reactions was investigated. These results are reported in this paper.

Experimental

Reagents Vanadyl sulfate (VOS0.J was purchased from Aldrich Chemical Co. Ltd. and used without further purification. Ammonium metavanadate (NI&VOJ) was obtained from Wako Pure Chemical Co. Ltd. NADH, superoxide dismutase (SOD) and catalase were from Sigma Chemical Co. and used as received. *Author to whom correspondence should be addressed.

0020-1693/91/$3.50

1

A water-soluble spin-trap, cu-(Cpyridyl-l-oxide)-N-tbutylnitrone (POBN, 1)was from Aldrich Chemical Co. Ltd. and used without further purification. Other reagents were commercially available. Deionized and triply distilled water was used throughout.

Procedure VOS04 and NI&VOs were used as the V(IV) ion and V(V) ion, respectively. NADH has the absorption maximum at 340 nm (eJ4,,=6.2X 103 M-’ cm-‘) [ll], but its oxidized form, NAD+, does not have a maximum at 340 nm. Thus, the oxidation process of NADH can be followed by measuring the decrease of the absorption at 340 nm. Vanadyl sulfate dissolved in water was stable for several hours, but was not stable for overnight, therefore an aqueous solution of VOS04 should be freshly prepared. To detect the short-lived free radicals which may be formed during the oxidation of NADH by vanadium ion, POBN was used as the spin-trap in an aqueous solution.

0 1991 -

Elsevier Sequoia, Lausanne

164

All reactants except VOSO, were dissolved in phosphate buffer at pH 7.4 VOSO, was dissolved in water. Reactions were undergone in the phosphate buffer at pH 7.4. Spectral measurements The UV-Vis spectrum was measured by a Union Giken SM-401 spectrophotometer. The electron spin resonance (ESR) spectrum was measured by JEOLPE-1X and JEOL-RE-1X ESR spectrometers (Xband) with 100 kHz field modulation. ESR parameters were calibrated by comparison with a standard Mn2+/ MgO and l,l-diphenyl-2-picrylhydrazyl (DPPH, g = 2.0036).

Results and discussion Addition of V(W) ion to a solution of NADH in phosphate buffer (pH 7.4) brings about oxidation of NADH (Fig. 1, curve 1). On the other hand, curve 2 shows that the vanadate(V) ion did not enhance the oxidation of NADH. From these results, it is indicated that the active species for the oxidation of NADH is V(IV) ion. Oxidation of NADH by the V(IV) ion occurred in the presence of oxygen, but not in the absence of oxygen (Fig. 2). Further, the addition of SOD, which disproportionates superoxide ion (O,-) to oxygen (0,) and hydrogen pyoxide (H202), inhibited the oxidation of NADH by the V(IV) ion (Fig. 1, curve 3). However, addition of catalase, which can destroy H202 to give HZ0 and oxygen, did not show any effect on the oxidation of NADH (Fig. 1, 2.3

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Time (set) Fig. 1. Oxidation of NADH by V(IV) the presence of oxygen. Curve 1: 0.83 mM V(W); curve 2: 0.83 mM NADH curve 3: 0.83 mM NADH+ 0.34 mM ml SOD; curve 4: 0.83 mM NADH + 0.34 mg/ml catalase.

and V(V) ions in mM NADH+0.34 +0.34 mM V(V); V(W) +0.017 mg/ mM V(W) + 0.017

:

,,,’, , , , , , , , , , Time

100

200

(set)

Fig. 2. Oxidation of NADH (0) and in the absence (0) contained 1.00 mM NADH 7.4.

by V(W) ion in the presence of oxygen. Reaction mixtures and 0.25 mM V(W) at pH

Fig. 3. ESR spectrum observed from V(IV) ion in aqueous solution. ESR settings: microwave power, 10 mW, modulation amplitude, 0.07 mT, amplitude, 3.6~ 100; time constant, 0.3 s; scan time, 8 min.

curve 4). Further, addition of ethanol, which can trap the hydroxyl radical (-OH), did not inhibit the oxidation of NADH. These results indicate that 02may be formed during the oxidation of NADH in the presence of oxygen. Furthermore, to ascertain the formation of 02during the oxidation of NADH by the V(IV) ion, ESR spin-trapping experiments were carried out. When the ESR spectrum was measured immediately after the V(IV) ion (0.2 mM) had been mixed with NADH (5 mM), the ESR spectrum due to the V(W) ion (Z = 7/2) consisting of 8 lines (av(Iv) = 11.61 mT, g= 1.998) as shown in Fig. 3 completely disappeared, but no new signal due to a secondary radical was observed. However, when POBN was added to the aqueous solution of NADH before the two reactants were mixed, a doublet of triplet ESR signal was observed as shown in Fig. 4(a). This signal can be analyzed as follows: a”(l)= 1.51 mT, aH(2)=0.17 mT and g=2.004. Addition of SOD to the NADH solution before the V(IV) ion was mixed caused the

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